CS218039B1 - Connection for connecting peripheral devices to power voltage - Google Patents

Abstract

The invention relates to a circuit that is used to connect computer peripheral devices to the mains voltage. The circuit is simple in design, has lower power consumption and the possibility of easy adjustment of the waiting time and start-up time. In""'" its essence lies in the use of electronic elements, in this case two mono· stable flip-flops and the associated two-input and three-input circuits of the logical product negation type, also: inverters and a transistor with the use of other common electrical elements arranged as shown in Fig. 1 of the drawings. The circuit can be used for any type of peripheral devices.

Description

BACKGROUND OF THE INVENTION The present invention relates to circuitry for connecting computer peripheral devices to mains voltage.

To reduce power consumption, mechanical wear on the mechanical portion of peripheral devices used on the output side of computers, such as punches, writing units, printers, and the like, is disconnected from the line voltage when not in use during computer operation.

This disconnection and then the connection is controlled by a computer. The hitherto known involvement in carrying out this activity is quite complex.

The above-mentioned disadvantages are eliminated by the circuitry for connecting computer peripheral devices to the mains voltage according to the invention, which is characterized in that the input command signal terminal for the computer connection is connected to the input for triggering the leading edge of the first monostable flip-flop; whose output is connected via a third inverter to the output command signal terminal for connection to a peripheral device, the falling edge starting input of the first monostable flip-flop is connected to the first neutral terminal, the second zero voltage terminal is connected through the first inverter to the neutral input a first monostable flip-flop whose direct output is connected to the first input of the three-input logic product type, to the input for the rising edge of the second monostable flip-flop the first output of the monostable flip-flop is connected to the input of the second inverter, whose output is connected through the third resistor to the third positive voltage terminal and through the fourth transistor-based resistor, the input for external connection capacitance of the first monostable flip-flop is connected via the first capacitor to the external resistance input connected through the first resistor to the first positive voltage terminal, the falling edge triggering input of the second monostable flip-flop is connected to the third zero voltage terminal, the output of the dual input type the negation of the logic product is connected through the third capacitor to the fourth negative voltage terminal and to the neutral input of the second · monostable flip-flop, whose negated output is connected to the second input of the two-input logic component negation and the third input of the three-input circuit type negation logic product, the input for connecting the external capacity of the second monostable flip-flop is connected through the second capacitor with its input for connecting the external resistor connected through the second resistor to the second positive voltage terminal; the fifth terminal for the zero voltage, while its collector via the relay to the fourth terminal for the positive voltage, the terminals for the mains voltages are connected through the make contacts of the relay to the terminals for the mains supply voltage of the peripheral device.

The advantage of the circuitry for connecting the computer peripheral devices to the mains voltage according to the invention, in addition to eliminating these disadvantages, is its simplicity, lower power consumption and the possibility of easily adjusting the waiting time and the starting time.

An example of a wiring for connecting computer peripheral devices to the mains voltage according to the invention is shown in the attached drawings, in which Fig. 1 is a wiring diagram; Fig. 2 is a wiring diagram.

Terminal 010 for the input command signal C — IN for connection to a computer (not shown) is connected to the input for loading edge 012 of the first monostable flip-flop MK01 and the second input of the logic product negation type three-input NST circuit. C — OUT output signal for connection to a peripheral (not shown). The falling edge input 011 of the first monostable flip-flop MK01 is connected to the first terminal 1 for zero voltage. The second neutral terminal 2 is connected via the first INV1 inverter to the reset input 013 of the first monostable flip-flop MK01, whose direct output 001 for the Q1 signal is connected to the first input of the three-input NST circuit, to input 022 monostable flip-flop MK02 and the first input of the two-input NSD circuit of the negation of the logical product. The negated output 002 for the Q1 signal of the first monostable flip-flop MK01 is connected to the input of the second inverter INV2, the output of which is connected via a third resistor R3 to a third positive voltage terminal 13 and via a fourth resistor R4 based on the transistor TR. The external capacitance input 014 of the first monostable flip-flop MK01 is coupled via the first capacitor C1 to the external resistance input 015 connected via the first resistor R1 to the first positive voltage terminal 11. The falling edge input 021 of the second monostable flip-flop MK02 is connected to the third terminal 3 for zero voltage. The output of the two-input logic product negation NSD is connected through the third capacitor C3 to the negative terminal 4 and to the reset input 023 of the second mono-stable flip-flop MK02 whose negated output 0021 for Q2 signal is connected to the second input of the negation logic product and the third input of the three-input NST circuit of the logic product negation type. Input 024 for

With the connection of the external capacity of the second monostable flip-flop MK02, it is connected via the second capacitor C2 to its input 025 for connecting an external resistor connected via the second resistor R2 to the second positive voltage terminal 12. The emitter of the transistor TR is connected to the fifth terminal for zero voltage, while its collector via relay F is connected to the fourth terminal 14 for positive voltage. A protective diode D and a protective resistor R5 in series are connected in parallel to the relay F. The mains voltage terminals 21, 22 are connected via the make contacts f1, Ϊ2 of the relay F to terminals 23, 24, which are used to supply the mains voltage to a peripheral device (not shown).

When the peripheral device is to be activated, the input command signal C — IN is sent to terminal 010 from the computer. This causes a Q1 signal of length T1 = R _T1 at the direct output 001 of the first monostable flip-flop MK01. C _T1 , corresponding to the waiting time, while on the negated output 0021 of the second monostable flip-flop MK02 the signal Q2 with the length T2 = R _T2 . C _T2 , which is the start-up time and which results in the level decreasing from logical 1 to logical 0 during this time. When this drop is complete and the Q2 signal is again at logic 1, the logic 0 negation of the three-input NST circuit will appear whenever the logic level C 1 IN signal at terminal 010 is energized. transistor TR and the armature of relay F and thus the connection of the mains voltage to the periphery (not shown) occurs when the direct output MK01 goes from logic 0 to logic 1 and lasts for the duration of the pulse Tp.

0010 is the input command signal C OUT at a logic 1 whenever the logic _levels: on one of the input command signal C IN appears at terminal 010, but only after the starting time T2.

Start-up time T2 is used for full start-up especially of mechanical parts of peripheral equipment, eg electric motors and the like. After the start time T2 has elapsed, it is possible for the input command signal C-IN to pass through the wiring logic to its output terminal 0010 and through it to the input of a peripheral (not shown) to which it thus commands to perform a certain operation such as printing, punching.

If during the waiting time T1 no further input command signal C-IN arrives at terminal 010, after one operation of the peripheral device the waiting time T1 and with it the signals Q1 and Q1 also end. The transistor TR is closed, the contacts f1, f2 of the relay F are opened and the peripheral device is disconnected from the mains voltage.

If during the waiting time T1 and after the start-up time T2, that is, at time T = T1-T2, even after performing one operation, another input command signal C-IN arrives at terminal 010, this signal passes through the connection logic to output terminal 0010. At the same time, it causes the waiting time to be extended by the length T1 from the moment of the arrival of this further command signal.

The starting time T2 can be adjusted as required by selecting the value of the second resistor R2 and the second capacitor C2. The waiting time Tl can be set by selecting the value of the first resistor R1 and the first capacitors C1.

The wiring can be used for any type of peripheral device.

Claims (1)

SUBJECT Connection for connection of computer peripheral devices to mains voltage, characterized in that the terminal (010) for the input command signal for connection to the computer is connected to the input (012) for starting by the leading edge of the first monostable flip-flop (MK01) and the second input of the three-input circuit (NST) logic product negation type, the output of which is connected via a third inverter (INV3) to the terminal (0010) for an output command signal for connection to a peripheral device, the falling edge input (011) of the first monostable flip-flop (MK01) connected to the first terminal (1) for neutral voltage, the second terminal (2) for neutral voltage is connected via the first inverter (INV1) to the neutral input (013) of the first monostable flip-flop (MK01), whose direct output (001) is connected to the first input of three-input circuit (NST) of the type of negation of logic product, to input (022) The leading edge of the second monostable flip-flop (MK02) and the first input of the two-input circuit (NSD) of the logic product type, the zero output (002) of the first monostable flip-flop (MK01) is connected to the second inverter (INV2) input. via a third resistor (R3) to a third positive voltage terminal (13) and via a transistor (TR) based fourth resistor (R4), the input (014) for connecting the external capacity of the first monostable flip-flop (MK01) is connected through the first capacitor ( C1) with an input (015) for connecting an external resistor connected via a first resistor (R1) to the first positive voltage terminal (11), the falling edge input (021) of the second monostable flip-flop (MK02) is connected to the third terminal ( 3) for zero voltage, the output of the logic product negation 2-input circuit (NSD) is connected through the third capacitor (C3) to the fourth negative terminal (4) voltage and to the reset input (023) of the second monostable flip-flop (MK02), whose negated output (0021) is connected to the second input of the two-input logic product negation (NSD) and the third input of the three-input logic product negation the input (024) for connecting the external capacity of the second monostable flip-flop (MK02) is connected via the second capacitor (C2) to its input (025) for connecting the external resistor connected via the second resistor (R2) to the second positive terminal (12) voltage, the emitter of the transistor (TR) is connected to the fifth neutral terminal (5), while its collector via relay (F) is connected to the fourth positive voltage terminal (14), while the mains voltage terminals (21, 22) are connected via make contacts (fl, f2) of relay (F) on terminals (23, 24) for mains voltage supply of peripheral equipment.